WO1995013030A1 - Separator unit and suction unit for dental work - Google Patents

Abstract

A separator unit for separating liquid out of an air-liquid mixture generated at a central work station comprises a separator wheel (52) with radial accelerator blades (66) that rotates within a housing. Two frontal plates (68, 96) and a central dividing wall (58, 78) delimit a winding passage for airflow from the inlet nozzle (26) to a first outlet nozzle (44) of the housing. The two frontal plates (68, 96) also feature a liquid discharge slot connecting with a second outlet nozzle (48) of the housing. In this way liquid portions of the suctioned mixture are reliably separated through centrifugal force even when small quantities of air are drawn through the separator unit.

Description

 Separation unit and suction unit for dental purposes

The invention relates to a separation unit for separating air from the mixture of air on the one hand and liquid and, if appropriate, additional solid particles on the other hand, and a dental suction unit in which such a separation unit is provided.

Cyclones are usually connected upstream of the suction machines of dental workstations on the inlet side in order to remove liquid components from the intake air. The degree of separation of these separation units must be good so that no liquid gets to the suction machine even in long-term operation, as a result of which the latter would be damaged.

Cyclones of this type are relatively large in the axial direction and require certain minimum air speeds. For some applications it would now be pleasant to be able to work even with smaller air throughputs without the risk of liquid penetrating through to the suction machine.

The present invention is therefore intended to further develop a separating unit according to the preamble of claim 1 in such a way that good separation of liquid constituents of the sucked-in mixture is ensured even at low air flow rates.

This object is achieved according to the invention by a separation unit according to claim 1. In the separation unit according to the invention, a strong circular movement is impressed on the inflowing mixture of air and liquid by the separating wheel, on the basis of which the separation into light and heavy components then takes place. According to the invention, the separating wheel is designed so that, on the one hand, a strong and long-lasting effect of centrifugal forces is obtained, on the other hand, the air is forced to flow from the inlet port to the first outlet port in a tortuous way and a safe discharge of the separated liquid into the second outlet port is ensured.

If, according to claim 22, such a separating unit is blocked with a suction machine and if the separating wheel is placed on the shaft of the suction machine, this good liquid separation can be obtained with little mechanical effort. The entire unit consisting of the suction machine and the separation unit is short in the axial direction. It is also easy to assemble.

Advantageous developments of the invention are specified in the subclaims.

If the acceleration vanes are given a planar shape running in the radial direction, then there is a particularly low flow resistance of the separation unit for sucked-in air.

The development of the invention according to claim 3 is advantageous with regard to a particularly safe discharge of separated liquid constituents and the building up of a higher pressure in the liquid dispensed. The development of the invention according to claim 4 is advantageous with regard to the prevention of leakage paths in the interior of the housing of the separating unit, which bypass the separating wheel.

The development of the invention according to claim 5 is used for a good unimpeded delivery of the separated liquid components.

In a separation unit according to claim 6 it is ensured that larger solid particles which are separated together with the liquid components do not get between the separation wheel and the housing, but rather roll away from the separation wheel under the action of gravity.

The development of the invention according to claim 7 also has the purpose of avoiding jamming of solid separated particles between the housing and the separating wheel of the separating unit.

In a separation unit according to claim 8, the mixture to be dismantled is taken over by the acceleration vanes in the immediate vicinity of the inlet connection.

The development of the invention according to claim 9 is advantageous with regard to favorable flow behavior in the area of the inlet connector and the inlet opening of the separating wheel.

The development of the invention according to claim 10 also serves the same purpose.

In a separation unit according to claim 11, around the leakage paths, which lead around the separating wheel inside the housing of the separating unit, are throttled.

The development of the invention according to claim 12 serves to guide the air flow on a path free of sharp edges from the inlet connector of the housing to its first outlet connector.

In the case of a separation unit according to claim 14, liquid drops running on the outside of the partition are thrown off at the outer peripheral rib of the partition and thus reach the liquid discharge gap of the separating wheel in a controlled manner.

The development of the invention according to claim 15 is advantageous with regard to the return of liquid components which, in the case of very unfavorable working conditions, may have come close to the outlet connection.

The development of the invention according to claim 16 is advantageous with regard to a soft deflection of the air flow moved by the separating wheel towards the outlet connection.

The development of the invention according to claim 17 serves to further suppress leakage currents by means of dynamic sealing.

A further improvement in leakage current suppression is obtained with the development of the invention according to claim 18.

The development of the invention according to claim 19 serves an improved flow behavior of the air drawn through the separation unit.

With the development of the invention according to claim 20 it is achieved that from the outlet opening of the

Air flowing out of the separating wheel forms a small vortex at the inlet of the outlet connection, which serves as a dynamic sliding bearing for the main air volume.

The development of the invention according to claim 21 allows the production of the separating wheel from a few plastic injection molded parts or metallic injection molded or cast parts and thus at low manufacturing costs.

A suction unit, as specified in claim 22, is characterized by a compact construction and low manufacturing costs.

The development of the invention according to claim 23 is advantageous with regard to the low flow resistance of the entire suction unit, for which only a relatively low power drive motor therefore needs to be provided.

The invention is explained in more detail below on the basis of an exemplary embodiment with reference to the drawing. In this show:

1 shows an axial section through a separation unit for separating liquid from the mixture of liquid and air occurring at a dental work station; and

2 shows an axial section through a suction machine, the inlet of which is connected to the outlet of the one in FIG shown separation unit is connected.

In FIG. 1, 10 denotes a separation unit, which together with a suction machine shown in FIG. 2, there designated a total of 20, forms a suction unit for a dental practice.

The separation unit 10 has a housing which consists of a lower housing part 22 and an upper housing part 24.

The lower housing part 24 has a downward-facing inlet connection 26 which, when the separating unit is ready for operation, is connected to the tray of a dental work station, to which a suction cannula, a saliva lifter and other vacuum consumers of the work station are then connected.

A first conical wall section 28 adjoins the inlet connection 26 at an angle of approximately 78 ° to the connection axis, followed by a second conical wall section 32 via a curved wall section 30, the surface lines of which form an angle of approximately with the connection axis Include 45 °.

Adjoining the wall section 32 is a wall section 34 which slopes downwards, the radially outer edge of which carries a spiral wall section 36 which runs in the circumferential direction. A last cranked wall section 38 cooperates with a folded wall section 40 provided on the edge of the upper housing part 24 in order to tightly connect the two housing parts 22, 24. In addition, the upper housing part 24 has a substantially cylindrical, upwardly raised wall section 42 which carries a first outlet 44. This is connected to an inlet connection 46 of the suction machine 20. A second outlet connection 48 is connected to an outlet channel 50 which is predetermined by the wall sections 36, 38 at its widest point.

In the space delimited by the two housing parts 22, 24, a separating wheel, designated overall by 52, is rotatably arranged with little play. The separating wheel 52 sits on a drive shaft 54 which is common to the separating unit 10 and the suction machine.

The separating wheel 52 is a component composed of three molded parts.

A first molded part 55 includes a hub portion 56 which is connected to the drive shaft 54 and carries a substantially transverse partition portion 58 which is tapered in the vicinity of the hub portion 56 towards the inlet port 26, as indicated at 60. The first molded part 55 also includes acceleration vanes 62, which essentially have the shape of a carrot angled at 90 °. The essentially transverse section of the wing is designated 64 in the drawing, the substantially axial wing section 66.

The lower edge of the acceleration wing 62 in FIG. 1 has an end plate 68 lying radially outside the edge of the partition wall section 58, which has a central inlet opening 70 of the separating wheel which runs inclined towards the edge of the inlet connector 26 52 specifies. Like the lower housing part 22, the end plate 68 has a first end plate section 72 set at approximately 78 ° to the separating wheel axis and a second conical end plate section 74 set at approximately 45 ° to the separating wheel axis.

Discharge vanes 76 are also formed on the edge of the end plate 68 and are provided distributed between successive acceleration vanes 62 in the circumferential direction. The radially outer portions of the acceleration vanes 62 have the same geometry as the discharge vanes 76.

A shell-shaped second injection-molded part 78 is placed on the partition wall section 58, the bottom wall 80 of which represents a continuation of the partition wall section 58 and merges into a cylindrical wall section 84 via a conical wall section 82. At the two ends of the conical wall section 82, drip ribs 86, 88 running in the circumferential direction are provided on the outside of the molded part 78. Openings 90 are provided at the lower end of the wall section 84. In the interior of the molded part 78, wings 92 are provided which run in the radial direction.

As can be seen from FIG. 1, the underside of the injection-molded part 78 essentially follows the contour of the upper edge of the acceleration vanes 62 and, together with the top of the end plate 68, delimits a tortuous annular channel, the cross-section of which initially decreases from the inlet connector 26 to the drip fin 86 and then widens again from there, at the same time the axis of the flow cross-section is increasingly shifted in the axial direction. The ends of the wing sections 66 located at the top in FIG. 1 carry a third molded part 94 which defines a second end plate 96 which is concavely curved as seen from the inside of the separating wheel. The edge of the end plate 96 is offset radially inwards to the edge of the end plate 68, so that the upper section of the discharge vanes 76 and the corresponding end section of the acceleration vanes 62 are free at the top. In this section of the discharge vanes 76 and the acceleration vanes 62, notches 98 are provided which run with little play over a rib 100 of the upper housing part 24 hanging downwards.

Similarly, notches 104, 106 are provided in radial wings 102, which protrude upward from the upper side of the end plate 96, and which cooperate with small play with ribs 108, 110 which project downward from the bottom of the wall section 42. In this way, a dynamic and labyrinth seal is obtained between the upper side of the separating wheel 52 and the upper housing part 24.

In the essentially vertical marginal edges of the radial wings 102, further notches 107 are provided which, with a circumferential rib 111, likewise form a labyrinth seal which is effective on the circumference of the third molded part 94. The rib 111 is carried by a substantially axially parallel, vertical wall section 113, which delimits the wall section 42 and is substantially flush with the rib 100.

As can be seen from FIG. 1, the end plate 96 has the shape of a concavely curved channel which, at the outer end, collects the air flow that is essentially already exiting in the axial direction between the molded part 78 and the end plate 68, over the edge of the leads second injection part 78 and then dispenses in the immediate vicinity of the first outlet 44.

As can be seen from FIG. 1, the outlet connection 44 has a conically tapering end section 112 which is pulled down a small distance h below a separating wheel outlet opening 114 which is predetermined by the inner edge of the molded part 94. A small toroidal vortex is thus generated by the small amount of air abutting the end section 112, which serves as a dynamic slide bearing for the main amount of the air drawn through the separation unit 10 and supports its deflection into the outlet connection 44.

As can be seen from FIG. 2, the suction machine 20 has a housing, designated overall by 116, which in practice can consist of several housing segments, the separating surfaces of which are selected in a suitable manner. An upper section of the drive shaft 54 is mounted in axially spaced bearings 118, 120, which in turn are each fastened to the housing 116 via three arms 122 distributed in the circumferential direction.

A rotor, designated overall by 124, is essentially an aluminum casting with a hub section 126 connected to the drive shaft 54 and a circumferential section 130 carried by the latter via fan blades 128. The latter has axial recesses 132, in which permanent magnets 134 are inserted . These work together with a rotating field, which is generated by a schematically indicated stator 136.

The suction unit shown in the drawing works as follows: The suction machine 20 sucks the resulting mixture of liquid and air from the workplace, which thus reaches the inlet port 26. By means of the separating wheel 52 seated on the drive shaft 54, the sucked-in mixture is set into a rapid rotary movement, whereby a separation between light and heavy components is obtained. The liquid and any solid constituents contained in the sucked-in mixture are pressed by the separating wheel 52 into the outlet channel 50 and the second outlet nozzle 48 connected to it. The pressure built up in the liquid is so great that a corner valve 138 can thereby be opened, via which the second outlet connection 48 can be connected to a sewage line under atmospheric pressure.

The light air fractions of the sucked-in mixture, on the other hand, flow via the outside of the second injection part 78 and the inside surface of the concave third injection part 94 to the first outlet port 44 and from there through the rotor 124 of the suction machine 20 to the ambient atmosphere.

The separation unit 10 ensures that liquid portions of the sucked-in mixture are reliably kept away from the suction machine 20.

If there are larger solid particles in the separated liquid, they move radially outward on the inclined wall section 34, that is to say away from the separating wheel 52. A lug 140 additionally provided in the circumferential direction on the inside of the wall section 34 locally further reduces the space between the separating wheel 52 and the lower housing part 22, so that no larger solid particles between the underside of the separating wheel 52 and the housing part 22 can enter and then find solid particles passing by the nose 140 without jamming back to the inlet port 26.

As can be seen from the drawing and the description above, the entire suction unit is axially short and has a mechanically simple structure. The degree of separation of the separation unit 10 does not depend on the amount of air drawn through it and its flow speed, but rather is determined by the speed of the drive shaft 54.

The essential features of the separation unit described above can be summarized as follows:

A separating unit for separating liquid from the mixture of air and liquid occurring at a central work station comprises a separating wheel 52 rotating in a housing with radial acceleration vanes 66. Two end plates 68, 96 and a central separating wall 58, 78 delimit a tortuous one Flow path for air from the inlet port 26 to a first outlet port 44 of the housing. The two end plates 68, 96 further define a liquid discharge gap which is connected to a second outlet connection 48 of the housing. In this way, liquid components of the sucked-in mixture are reliably separated by centrifugal force even if only small amounts of air are drawn through the separation unit.

The air is guided inside the separating unit with a first deflection of approximately + 90 °, a second deflection of approximately -180 ° and a third deflection of approximately + 90 °.

Claims

claims 1. Separation unit for separating liquid from that occurring at a dental work station Mixture of air on the one hand and liquid and optionally additional solid particles on the other hand, with a housing (22, 24) which has an inlet connection (26) for the mixture to be dismantled and a first outlet connection (44) for air and a second outlet connection ( 48) for liquid and possibly solid mixture components, and with means for rapidly rotating the supplied mixture, characterized in that the means for rotating the mixture have a separating wheel (52) which has a first end plate (68) on the inlet side , which is essentially frustoconical and defines an inlet opening (70) adjacent to the inlet connection (26), has a partition (58, 78) through which a direct flow connection between the inlet connection (26) and the first outlet connection (44) is interrupted, and which has an outlet-side, second end plate (96) which one of the first outlet connector ( 44) specifies an adjacent outlet opening (114), the edges of the two end plates (68, 96) delimiting a radially outer liquid discharge gap of the separating wheel (52); that acceleration wings (62) with a radial extension component are provided in at least part of the space between the first end plate (68) and the partition (58, 78); and that inlet connector (26) and first outlet connector (44) of the housing (22, 24) are arranged coaxially. 2. Separation unit according to claim 1, characterized gekennzeich¬ net that the acceleration wing (62) seen in the axial direction extend in radial planes. 3. Separation unit according to claim 1 or 2, characterized in that in the liquid discharge gap of the separating wheel (52) discharge vanes (66, 76) are arranged. 4. separation unit according to claim 3, characterized gekennzeich¬ net that the edge of the second end plate (96) is offset radially inward to the edge of the first end plate (68) and that in the free outlet-side edges of the discharge wing (66, 76) notches ( 98) are provided which run with little play over a rib (100) carried by an outlet-side end wall (42) of the housing (22, 24). 5. Separation unit according to one of claims 1-4, characterized in that the housing (22, 24) one of the liquid discharge gap of the separating wheel (52) surround the, widening in the direction of rotation outlet channel (50), the widest section with the second Outlet connector (48) is connected. 6. Separation unit according to claim 5 for operation with the vertical alignment of the separating wheel axis, characterized in that a bottom wall (34) of the outlet channel (50) slopes downwards in the radial outward direction. 7. Separation unit according to claim 5 or 6, characterized in that the edge of the outlet channel (50) facing the first end plate (68) has an in In the circumferential direction to the free edge of the first end plate (68), the rib (140) protrudes and lies at a short distance in front of it. 8. separation unit according to one of claims 1-7, characterized in that the acceleration vanes (62) extend radially inward over the edge of the inlet opening (70) towards the axis of the separating wheel (52). 9. Separation unit according to one of claims 1-8, characterized in that the first end plate (68) has an inlet-side end plate section (72) which is more inclined to the separating wheel axis and a subsequent end plate section which is more inclined to the separating wheel axis (74). 10. Separation unit according to claim 9, characterized in that the inlet opening (70) has a wall surface inclined towards the inlet connector (26). 11. Separation unit according to one of claims 1-10, da¬ characterized in that the inlet port (26) bearing inlet-side end wall (28-32) follows the opposite surface of the first end plate (68) of the separating wheel (52) at a small distance. 12. Separation unit according to one of claims 1-11, characterized in that the partition (58, 78) has the shape of a shell open towards the first outlet connection (44). 13. Separation unit according to claim 12, characterized in that an essentially axially parallel edge-side wall section (84) of the partition (58, 78) is provided with openings (90). 14. Separation unit according to claim 13, characterized gekennzeich¬ net that the partition (58, 78) on its the first End plate (68) facing surface with at least one outer peripheral rib (86, 88) is. 15. Separation unit according to one of claims 1-14, characterized in that the partition (58, 78) on its side facing the first outlet (44) is provided with a radial extension component having conveying vanes (92). 16. Separation unit according to one of claims 1-15, characterized in that the second end plate (96) forms a concave groove seen from the inside of the separating wheel (52). 17. Separation unit according to one of claims 1-16, characterized in that the housing (22, 24) facing side of the second end plate (96) carries wings (102) with a radial extension component. 18. Separation unit according to claim 17, characterized in that the wings (102) carried by the second end plate (96) have at least one notch (104, 106, 107), which with little play over one of the opposite end wall of the housing (22, 24) supported rib (108, 110, 111) run. 19. Separation unit according to one of claims 1-18, da¬ characterized in that the first outlet port (44) has a frustoconical wall section (112) which widens conically in the direction away from the partition (58, 78). 20. Separation unit according to one of claims 1-19, characterized in that the edge of the first outlet nozzle (44) adjacent to the separating wheel (52) axially slightly above the adjacent edge of the through the second end plate (96) limited outlet opening (114) of the separating wheel (52) protrudes (h). 21. Separation unit according to one of claims 1-20, characterized in that the first end plate (68), the acceleration vanes (62) and a section (58) of the partition wall (58, 78) which is axially aligned with the inlet opening (70) of the separating wheel (52) and a hub section (56) of the separating wheel (52) one-piece first molded part (55) are formed and the rest of the partition (58, 78) and the second end plate (96) are formed by a separate second (78) and third (94) molded part, the three molded parts ( 55, 78, 94) locked together or permanently connected to each other, e.g. B. by gluing or welding. 22. Suction unit for a dental work station with a separation unit for separating liquid from the mixture of air on the one hand and liquid and, if appropriate, additional solid particles on the other hand, and with a suction machine that is connected to the air outlet of the separation unit, characterized in that that the separation unit is a separation unit (10) according to one of claims 1-21 and that the suction machine (20) comprises an axial fan, in particular a vacuum cleaner fan. 23. Suction unit according to claim 22, characterized in that the fan wheel (128) of the suction machine (20) in the rotor (124) of the drive motor (124, 136) is formed.